We employed all-atom molecular dynamics simulation and quantum mechanical methods to explore the relationship between molecular conformation and UV absorption spectra of polythiophene-based conducting polymers. The UV spectrum of 3HT monomer was observed in blue-shift, because of the deviation from coplanar of main chain; the D4QT was found in red-shift, due to the torsional deviation and competitive effect between conjugated main and side chain. In the ordered state, the P3HT and PDBT chains experience the pi-pi interaction and result in more coplanarity for main chain. Thus, they show significantly red-shift with increasing repeated unit. The absorption spectrum of PD3QT was shown in single peak, because the competitive effect of restricting electron could not be offseted and the coplanarity between side and main chain could be maintained. The torsional angle of PD4QT were shown in symmetry and located in 115o and 245o. Hence, the red-shift of PD4QT is more significant than PD3QT and shown in two peaks of spectrum. In the disordered state, the chain conformation is shown in coil conformation within dilute solution and the persistence length in disordered state is shorter than in ordered state. The persistence length of P3HT, PDBT, PD3QT and PD4QT are located in 3 to 5 repeated units by theoretical calculation. Therefore, the UV spectra for P3HT and PDBT or PD3QT and PD4QT are similar. Besides, our simulated spectrum for P3HT in disordered state showed the excellent agreement with experimental data. These results illustrate our methods is reliable.